Väino Tarandi Professor, KTH. Årskonferens Centrum för Byggeffektivitet, Stockholm

Fokusgrupp Informationshantering och Digitalisering Behovet av interoperabilitet och öppna standarder i byggsektorn integration av BIM och GIS ur ett livscykelperspektiv Väino Tarandi Professor, KTH Årskonferens 2017 - Centrum för Byggeffektivitet, Stockholm 2017-10-25

Informationshantering och digitalisering» Fokusgruppen Informationshantering och digitalisering vill studera och utveckla det obrutna informationsflödet i byggsektorn över hela processen från planering över projektering och produktion till drift och förvaltning.» Olika digitaliserade flöden och tillämpningar ska kunna hanteras med öppna och standardiserade format, helst på internationell bas.» Grunden för detta är en gemensam nationell informationsplattform. Stora möjligheter finns till en allt effektivare produktion, eftersom mängden digitaliserade processer ökar för att på sikt omfatta det mesta vi bygger och förvaltar.

Så här ser det ut. (för bygg)» BIM, GIS och infrastruktur inte integrerade» Få modeller för produktion eller förvaltning - trots ambition i designskedet Undervisningshuset på KTH ett exempel Förvaltningen ställer inga krav» Stadsmodeller Inga öppna standarder Stuprör per leverantör av IT och sensorer» Sensorer Inte kopplade till modeller Ingen analys eller styrning

Trender» Digitalisering» Cirkulär ekonomi, design & produkt» Digital Twin / Digital Thread Kräver livscykelstöd "typ" PLCS Stödjer LCA, cirkulär design, simulering & analys» ISO/IEC JWG 21 Standardisering av IoT, Smart Manufacturing & Industry(ie) 4.0 Stort svenskt deltagande Ericsson, Sandvik, Siemens, KTH, LTH m fl

Digitalisering

Cirkulär ekonomi - delningsekonomi

Digital Twin & Digital Thread

ISO/IEC JWG 21

Vår forskning och utveckling - Testbädden

Testbed for BIM level 3 Testbed for Interoperability Lifecycle managemetn Common models, Conceptsand processes Processes drawings, documents models files objects data bases integrated BIM hub BIM levels after British Standards Institute (from ARCADIS adapted to Sweden)

Smart planning, design, construction, operation and use processes over the whole life cycle APPLICATION CASES Test case 2 Test case 4 Test case 1 Test case 3 Test case n TEST BED SMART INFORMATION PROCESSEs National geo data Municipality geo data Real estate register Etc Export, import, linking Converting, verifying (ETL) Country County City Block Property Geodata (Swedish Geo process) Linked data sources Visualisation Transport network Lifecycle support Building Floor Room Building element BIM (BIM Alliance) Converting, verifyiing (ETL) Export, import, linking National road db BIM Product database Etc.

Smart planning, design, construction, operation and use processes over the whole life cycle APPLICATION CASES Test case 2 Test case 4 Test case 1 Test case 3 Test case n TEST BED SMART INFORMATION PROCESSEs National geo data Municipality geo data Real estate register Etc Export, import, linking Converting, verifyiing (ETL) Country County City Block Property Geodata (Swedish Geo process) Linked data sources Visualisation Transport network Lifecycle support Building Floor Room Building element BIM (BIM Alliance) Converting, verifyiing (ETL) Export, import, linking National road db BIM Product database Etc.

Time schedule for the Test bed WP 1: Developmentof the platform, WP leader Torbjörn Holm, Eurostep WP 2: Information exchange construction company - municipality, WP leader Lars Harrie, Lund University WP 3: 3D property formation, WP leader Jenny Paulsson, KTH WP 4: BIM for production management, WP leader Thomas Olofsson, LTU WP 5: Management, information dissemination, WP leader Väino Tarandi, KTH Applied project Trafikverket VERA IFC Alignment tested in the test bed late autumn 2017 OOOOOOOOOOOO Participants KTH, LTU, LU, Chalmers, Högskolan i Gävle, Lantmäteriet, Trafikverket, Boverket, Mölndal stad, Stockholm stad, Malmö stad, Helsingborg stad, Eurostep, Triona, Trimble (Vianova), Agency 9, Logiq/Finfo, NCC, Tyréns, Cementa, Betongindustri, SLL Trafikförvaltningen

Project purpose This project proposal aims at creating a Level 3 test bed to be a national resource for testing concepts, ideas and innovations for the smart community. It involves tests of open new and existing standards, methods and processes to make available and use Geo and BIM data in several parts of the community building process throughout the project and city life cycles. The test bed will be used in cooperation between authorities like National Land Survey, National Board of Housing, Building and Planning, Swedish Transport Administration, municipalities, etc. and construction companies to develop and test a digital open, object oriented and standardized information exchange. "

Multiple Systems Integration? Collaboration Hub

Integration of standards for buildings and infrastructure Through Life Support - PLCS Net-work ISO 191xx based (NVDB, Inspire, etc.) Alignment Ifc, simple ifcxml Common concepts InfraGML Ifc, simple ifcxml, LandXML LandXML XML. XML.

Lifecycle + breakdown with topology Objectified topological relation (with effectivity) Life cycle phases Product breakdown [ISO 12006-2] Through life support (incl. versioning) [PLCS ISO 10303:239]

Heterogeneous data models mapped to PLCS Alignment Road, Railway Bridge InfraGML

Using PLCS and IFC (& more) PLCS» ISO 10303-239 Change Management Versioning Consolidation Requirement Product as realized Maintenance IFC» ISO 16739:2013 Building element Material Property Geometry Placement Other domain specific stds - LandXML, CityGML, InfraGML C O P Y R I G H T E U R O S T E P G R O U P

What IFC2x3 can do today Geometry (explicit) B-rep CSG Geometry (Sweep) volume - extrusion, rotation areas - extrusion, rotation Topology element connectivity, schematic design Relations between Building Elements Wall Connections Holes Chases Zones Spaces and Spatial Structure Space Building Storey Building Building Site Building Elements Walls, Openings, Doors Roofs, Stairs, Ramps, etc. Site and Terrain Model Site Site attributes C O P Y R I G H T E U R O S T E P G R O U P

The PLCS high level model C O P Y R I G H T E U R O S T E P G R O U P

Business processes Municipality Contractor Building permit 3D property Production management Information systems Train Train Agency9 Nova Point Minecraft System A System B System C System Mate MateX Standardised interfaces (ETL tools) Information Network TNE BIM / GIS object PLCS Documents Reference db Linked data sets City Block Building Room Road... Property register NVDB NNH Logic/Finfo

Architecture to implement 1. Topological & Spatial hierarchies 2. Versions and changes 3. Life cycle 4. Unique identifiers - GUID 5. Classification 6. Units 7. Coordinate systems 8. Reference geometries 9. Types with versions 10. LOD Level of Detail for the Geo process 11. Terrain model - granularity 12. Networks and Road alignments 13. Swedish Geo process

Topological & Spatial hierarcies Background In the GIS world, you usually use coordinates to search for information rather than topologis-ka relationship. In the BIM world, the IFC standard has evolved over a long period of time, and the structure of the building, floor, room and building elements has worked well to find and navigate among the different parts. Systems and topologies provide opportunities for analysis and comparisons of different locations in the country with recurring similar degradations. The idea is to have a simple, quick breakdown in a few steps. Suggestions for functionality in the platform Structures from county to city to neighborhood to property are being built up. To these networks, breakdowns in networks for wiring, roads m m from the appropriate level. Similarly, as the stories (spatial structure element) of the building has rooms, the Infra group in buildignsmart has developed traffic places with "spatial segments" - lanes, walkways, etc. For example, a roundabout, station area, sports facility has "spatial segments" - this is lacking in the classification systems...

Life-cycle model From a life-cycle perspective it is important to have an unbroken information flow. The different phases of the life-cycle for a construction project and the construction itself need to be represented by several objects, not just one, over time. The designed physical element, fulfilling requirements through its function, The product as planned realizing the technical solution and finally, The product as realized with its serial number.

Livscyle phases Description All stages and types of objects will be handled for detail planning, property development, construction, operation and management processes. Requirements management, design phases, types of items should be handled. It is difficult for the actors to address the requirements on the objects to be built when the requirements are usually presented in text documents instead of attributes associated with geographical or geometrical objects. Requirements are own objects (in PLCS) and they should not be viewed as attributes associated with the objects. In the built society there are existing buildings and facilities - they occur at different stages of determination, production, operation and maintenance. Similarly, there are planning processes in progress covering different parts of the built society. Suggestions for functionality The phases can be handled by giving the objects in information models different phase relations to be able to follow their changes over time. Previous work in EU projects and standardization of PLCS for manufacturing and defense industries, as well as buildings to some extent, supports that PLCS is proposed as a platform for lifecycle management in the platform, see the following pictures:

Type object to design object Physical_element Part Physical_element _version Part_version Physical_element _definition Part_view _definition Breakdown_element_realization

Type object to planned individual Product_as _individual Part Product_as _planned Part_version Product_as_ individual_view Part_view _definition Breakdown_element_realization Product_as_planned will later be replaced by Product_as_realized

Design object to planned individual Physical_element Product_as _individual Physical_element _version Product_design _version_to_individual Product_as _planned Physical_element _definition Product_as_ individual_view Product_as_planned will later be replaced by Product_as_realized

Classification Description The new classification system CoClass is now ready for use in Sweden. It covers both buildings and facilities. It has an object division that is extensive and soon also property definitions. CoClass is also intended to be used to identify components in different system structures. Alternative Use CoClass for pure classification of building objects. Watch out for the impact of system structures on identity setting. Other identification applications (designation) are possible as identities can be generated based on the systems and breakdowns that exist in the buildings if they are modeled correctly. Suggestions for functionality in the platform Build parallel structures according to the IFC Standard (Building, Spatial Structure Elements, Spaces and Building elements) also for facilities (and other "building complex" such as railway stations). The figure below shows a sports facility that should be structured in a similar way to a construction work. It should follow the structures of IFC - a breakdown from property to building and land, which is then broken down into a spatial and physical structure.

<BV>Track and Field Facility <UT>BDA Sport Area (Soccer field) <BX>Sport Arena <BV>APA Utility room <UT>GDB Green made rest area <UT>GAA Forest Sport arena, utility rooms and sport areas seem to be unstructured and mixed in this example?

Coordinate systems Description The question is which coordinate system will we primarily work in when designing? You can think of three alternatives: A national system Sweref 99 TM A municipal system - Local map projections by Sweref 99 Alternative - construction site-specific coordinate system Our proposal is that we should store in geographic coordinates and then convert. The Swedish Transport Administration only has latitude and longitude on its elongated projects - within the BIM area it is included as part of the IFC standard. Swedish geo process requires the Sweref 99 TM to be used (at least in their building model).

In IFC 4 the coordinates are definied for the project/site origo using IFC 4 geolocation, which has the following structure:

Engineering system the BIM world

Linking The BIM world is linked to the ellipsoid by a fixed point and a known orientation Map projections are determined by mathematical formulas, these vary depending on map projection

Reference geometries Description The IFC standard provides reference geometries for the relative locations of the individual objects (building elements) in relation to the site's origin or other building elements. These reference geometries may be insertion points, lines and surfaces for all different building components. They define the origin and rotation of the current object. Similarly, in Swedish geo process according to Measurement Instructions, see examples below.

LOD Level of Detail for the Geo process Description The test beds should be able to keep information and geometry for the various objects that form the built environment. Several different representations should be kept for both information and geometry using property sets and 2D / 3D models, respectively. On the GIS side, CityGML has its definition of LOD0, 1, 2, 3 and 4. For the BIM side, for example NIBS (USA) has its values 200, 300 etc. Alternative The LOD geometry on the building level (for Swedish geo process / CityGML) can be generated from BIM models (with appropriate software) or it can be created by using separate tools in the planning process to be independent of the design work. Definitions of building components will be created in the design process and directly linked to the BIM objects. Suggestions for functionality in the platform Generate LOD 0, 1, 2, 3 and 4 from the BIM models when they are imported to the platform. Placeholders are created at the building level for geometries (and properties) classified as respective LOD level. The LOD descriptions for the Swedish geo process are linked to the relevant version of the building as the details are developed. FME is a candidate as a tool. The definitions on the building level are imported via the BIM model and are linked to the respective stage and version.

OGCs Level of Definition

GIS standards vs BIM standards BIM-model Geodata-model Source: Nagel och Kolbe

Network and Road Alignments (IFC 4)

Swedish Geo process Process flows and information deliveries?

Vår forskning och utveckling - Nya testfall för Testbädden» Forskningsfrågor och utvecklingsprojekt inom KTH Undervisningshuset» IoT, sensorer, simuleringar m m» Samverkan Industriell Produktion, Gunilla Sivard» Akademiska Hus

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